Linkage relationship between two genes conferring resistance to peanut stripe virus and soybean mosaic

Summary The possible linkage relationship between hypocotyl color, leaflet shape, resistance to soybean mosaic virus (SMV) and to a soybean isolate of peanut stripe virus (PStV-isolate PN) was examined in two soybean lines AGS 129 and Ankur.Hypocotyl color, leaf shape and reactions to SMV-G1 and PStV were found to be inherited monogenically, with purple hypocotyl color, ovate leaf shape and resistance to both of the viruses being dominant. The reactions to SMV and PStV were conditioned by genes with 9 ± 2.4 percent recombination as coupling phase. They were inherited independently from hypocotyl color and leaf shape.     

Inheritance of resistance to Soybean mosaic virus in FT-10 soybean

The occurrence of a new isolate from the G5 strain of Soybean mosaic virus (SMV), which broke the resistance of soybean cultivar FT-10, was first reported in Brazil in 1995. Cultivar Davis is an ancestor of ‘FT-10’ and the likely source of resistance to the virus. Diallel crosses among resistant cultivars Epps (PI 96983), Ogden and FT-10, and susceptible cultivar Hill were made to investigate the inheritance of SMV resistance in FT-10. The experiments for genetic studies were performed undergreen house conditions. Plants of the F₂ population and F₃ families from each cross and the parents were inoculated with SMV G1 and G5 strains. Plants were classified as: symptom less (R), susceptible with typical symptoms of mosaic (S), and systemic necrosis (N). Plants showing necrosis or no symptoms were classified as resistant. Each F₃ family was classified as resistant (homozygous),susceptible (homozygous), or segregating (heterozygous). The results of both F₂ and F₃ were analyzed by Chi-square tests. The results suggested that FT-10 carries an allele at the Rsv ₁ locus for resistance to SMV. However, the allele is different from those in Epps and Ogden. The symbol Rsv ₁ ^d is a tentatively named for the newly detected allele in FT-10. This allele probably originated from Davis cultivar. This revised version was published online in July 2006 with corrections to the Cover Date.     

Inheritance of resistance and genetic relationships among soybean plant introductions to races of soybean cyst nematode

Summary The objectives of this study were to determine if genes for resistance to soybean cyst nematode (SCN) in soybean PI 437654 were identical or different from the genes in Peking, and PI 90763. The F₂ plants and F₃ families were studied from crosses between PI 437654, Peking, and PI 90763. The cross PI 437654 × susceptible Essex was included to determine inheritance of resistance to SCN. For Race 3, PI 437654 was found to have genes in common with Peking and PI 90763. The segregation in PI 437654 × Essex indicated the presence of one dominant and two recessive genes. For Race 5, PI 437654 indicated the presence of similar genes as those in PI 90763 and Peking whereas, PI 437654 × Essex indicated the action of the segregation ratios of two dominant and two recessive genes. For Race 14, the data from the cross PI 437654 × PI 90763 indicated monogenic inheritance with resistance being dominant; whereas PI 437654 × Peking showed a recessive gene controlling resistance. The segregation in PI 437654(R) × Essex(S) suggested one dominant and two recessive genes for Race 14 reaction.     

Inheritance and linkage analysis of resistance to zucchini yellow mosaic virus, watermelon mosaic virus, papaya ringspot virus and powdery mildew in melon

A melon (Cucumis melo L.) breeding line derived from PI 414723 is resistant to three potyviruses,watermelon mosaic virus (WMV), zucchini yellow mosaic virus (ZYMV), papaya ringspot virus (PRSV), and to powdery mildew (PM). The inheritance and linkage relationships of these four resistances were studied in a segregating F2 population and derived F3 families from a cross between cultivar Top Mark and the resistant breeding line. Dominant monogenic inheritance of all four resistances was observed. We report that line 414723-4S3, which was initially selected as a source of ZYMV and WMV resistance, is also a source of dominant monogenic resistances to PRSV and PM race 1. We also report on genetic linkage (significant departure from independent segregation, χ² = 58.1, p≪ 0.0001) between resistance to WMV and ZYMV. The map distance between these loci was estimated to be 7.5 cm. The genes for resistance to PM and PRSV segregated independently from each other, and from ZYMV and WMV resistance. This revised version was published online in July 2006 with corrections to the Cover Date.     

Resistance to soybean cyst nematode and molecular polymorphism in various sources of Peking soybean

Summary Cultivar Peking has been extensively used as a source of resistance to Race 3 and Race 5 of soybean cyst nematode, Heterodera glycines I., and Peking genes for resistance are present in a wide range of resistant soybean cultivars. Peking is also used as a host differential in the soybean cyst nematode race classification system. Thirteen Peking lines maintained in the USDA Soybean Germplasm Collection and in several breeding programs were surveyed using RFLP and RAPD markers for genetic characterization. Based on the molecular diversity combined with reaction to soybean cyst nematode, Peking genotypes from a common original source were identified. Peking lines PI 297543 (introduction from Hungary), and PI 438496A, PI 438496B and PI 438496C (introductions from Russia) represented unrelated germplasms. Identified molecular polymorphism can be used to validate the genetic purity of Peking lines used as host differentials for soybean cyst nematode classification system as well as utilization of an individual germplasm line in genetic-breeding programs.     

Characterization of resistance to Aphis glycines in soybean accessions

The soybean aphid, Aphis glycines Matsumura, is a pest of soybean [Glycine max L. (Merrill)] in Asia, and its recent establishment in North America has led to large, recurring outbreaks that have challenged pest management practitioners there to seek environmentally responsible means for its control. Growth-chamber experiments were conducted to determine and characterize host-plant resistance among several soybean accessions. Soybean plants were first screened for resistance by rating the population growth of A. glycines in two tests. All plants of PI 230977 and 25% of PI 71506 plants were resistant (≤100 aphids per plant) in the first screening test. All ‘Dowling’, PI 71506 and PI 230977 were resistant (≤150 aphids per plant), and 50% of plants of line ‘G93-9223’ were resistant in the second test. Follow-up experiments showed that antixenosis was a modality of resistance based on reduced nymphiposition by A. glycines on Dowling, PI 230977 and PI 71506 in no-choice tests and on fewer numbers of A. glycines on Dowling, PI 230977, PI 71506 and G93-5223 in distribution tests. Antixenosis in Dowling and PI 230977 was stronger in the unifoliolate leaves than in other shoot structures, whereas distribution of A. glycines within plants of PI 71506 and G93-5223 suggested comparable suitability between unifoliolate leaves and other shoot structures of these accessions. Antibiosis to A. glycines was evident as a lower proportion of aphids that reproduced on PI 230977 and from fewer progeny on PI 230977 and Dowling than on 91B91. The number of days from birth to reproduction by A. glycines did not differ among accessions. Results confirmed Dowling and PI 71506 as strong sources of resistance to A. glycines. The levels of antixenosis and antibiosis to A. glycines in PI 230977 and antixenosis to A. glycines in G93-9223 suggest that these accessions may also be valuable to soybean breeding programs as sources of resistance.     

小麦品种中梁21抗条锈病基因遗传分析与SSR标记定位

用7个我国当前流行的条锈菌生理小种评价中梁21的苗期条锈抗性,结果表明该品种对我国优势流行小种具有良好的抗性。采用CYR30小种对中梁21与铭贤169杂交的F₁、BC₁、F₂及F₃代群体进行遗传分析,并利用SSR分子标记进行遗传作图,发现中梁21对CYR30的抗性由1个显性基因控制,暂命名为Yrzhong21。该基因与位于小麦5AL染色体上的10个SSR位点Xgwm186、Xbarc165、Xwmc795、Xbarc40、Xgwm156、Xgwm617、Xwmc415、Xbarc151、Xwmc338和Xgwm666连锁,其中最近的侧翼位点为Xgwm186和Xbarc165,其遗传距离分别是7.5 cM和2.7 cM。系谱分析及结合分子标记结果表明,该基因可能来自Ciemenp。与已定位于5A染色体上的抗条锈病基因的比较表明,Yrzhong21可能是一个抗条锈病的新基因。用标记Xgwm186和Xbarc165检测中梁系列品种,其中仅17%扩增到与中梁21相同的位点,表明该基因在抗条锈病育种中可能有很大的应用潜力。     

Inheritance of resistance in soybean PI 567516C to LY1 nematode population infecting cv. Hartwig

Worldwide, cyst nematode (SCN) Heterodera glycines is the most destructive pathogen on cultivated soybean (Glycine max (L.) Merr.). In the USA yield losses in 2001 were estimated to be nearly 60 million dollars. Crop losses are primarily reduced by the use of resistant cultivars. Nematode populations are variable and have adapted to reproduce on resistant cultivars overtime because resistance primarily traces to two soybean accessions. Recently cv. Hartwig was released which has comprehensive resistance to most SCN populations. A virulent nematode population LY1 was recently selected for its reproduction on Hartwig. LY1 population originated from a mass mating of Race 2 (HG Type 1.2.5-) females with Race 5 (HG Type 1.2-) males. LY1 nematode population infects currently known sources of resistance except PI 567516C. The female indices obtained on PI 567516C and Hartwig were 7% (resistant) and 155% (susceptible), respectively. However, the genetic basis of LY1 resistance in soybean PI 567516C is not known. Resistant PI line 567516C was crossed to susceptible cultivar Hartwig to generate 105 F_2:5 families. These families together with parents, seven indicator lines and a susceptible control cv. Lee-74 were evaluated for response to LY1 nematode population in the greenhouse. Chi-square analysis showed resistance in PI567516C to LY1 was conditioned by one dominant and two recessive genes (Rhg, rhg, rhg). Chi-square value was 0.15 and P = 0.70. This information will be useful to soybean researchers for developing resistant cultivars to nematode population that infects Hartwig.     

Genetics of Cyst Nematode Resistance in Soybean PIs 467312 and 507354

Soybean Cyst nematode (SCN) Heterodera glycines Ichinohe is the most serious pest of soybean [Glycine max (L.) Merr.] in the world and genetic resistance in soybean cultivars have been the most effective means of control. Nematode populations, however, are variable and have adapted to reproduce on resistant cultivars over time due mainly to the narrow genetic base of SCN resistance in G. max. The majority of the resistant cultivars trace to two soybean accessions. It is hoped that new sources of resistance might provide durable resistance. Soybean plant introductions PI 467312 and PI 507354, are unique because they provide resistance to several nematode populations, i.e. SCN HG types 0, 2.7, and 1.3.6.7 (corresponding to races 3, 5, and 14) and HG types 2.5.7, 0, and 2.7 (corresponding to races 1, 3, and 5), respectively. The genetic basis of SCN resistance in these PIs is not yet known. We have investigated the inheritance of resistance to SCN HG types 0, 2.7, and 1.3.6.7 (races 3, 5, and14) in PI467312 and the SCN resistance to SCN HG types 2.5.7 and 2.7 (races 1 and 5) in PI 507354. PI 467312 was crossed to ‘Marcus’, a susceptible cultivar to generate F₁ hybrids, 196 random F₂ individuals, and 196 F_2:3 families (designated as Pop 467). PI 507354 and the cultivar Hutcheson, susceptible to all known SCN races, were crossed to generate F₁ hybrids, 225 random F₂ individuals and 225 F_2:3 families (designated as Pop 507). The F_2:3 families from each cross were evaluated for responses to the specific SCN HG types in the greenhouse. Chi-square (χ²) analyses showed resistance from PI 467312 to HG types 2.7, and 1.3.6.7 (races 5 and 14) in Pop 467 were conditioned by one dominant and two recessive genes (Rhg rhg rhg) and resistance to HG type 0 (race 3) was controlled by three recessive genes (rhg rhg rhg). The 225 F_2:3 progenies in Pop 507 showed a segregation of 2:223 (R:S) for response to both HG types 2.5.7 and 2.7 (corresponding to races 1 and 5). The Chi-square analysis showed SCN resistance from PI 507354 fit a one dominant and 3 recessive gene model (Rhg rhg rhg rhg). This information will be useful to soybean breeders who use these sources to develop SCN resistant cultivars. The complex inheritance patterns determined for the two PIs are similar to the three and four gene models for other SCN resistance sources known to date.     

大豆花叶病引起的大豆顶端坏死症

２个抗病亲本和２个感病亲本配制４个杂交组合和４个回交组合。调查其Ｆ１、Ｆ２和ＢＣＦ１群体接种东北大豆花叶病毒二号株系后，顶端坏死株的形成和分离比例。Ｆ１表现两种类型：无症株和坏死株，Ｆ２表现三种类型：无症株、有症株（花叶、皱缩等）和坏死株。其分离比例或为３抗：１感，或为７抗；９感，χ＾２测验符合一对显性基因控制或者两对隐性互补基因控制。     

Resistance and partial resistance to Phytophthora sojae in early maturity group soybean plant introductions

Phytophthora sojae, an important yield limiting pathogen of soybean, causes seed, seedling, root, and stem rots. Losses caused by P. sojae can be controlled by both major gene and partial resistance. Early maturity group (MG) soybeans are an increasingly important crop in northwestern Minnesota and eastern North Dakota. Early MG plant introductions (PIs) from the USDA Soybean Germplasm Collection and early MG public and private cultivars were evaluated for resistance and partial resistance to P. sojae. Of the 113 PIs, PI438445, and PI438454 exhibited resistance to P. sojae races 4, 7, 17, and 28 indicating they may possess either Rps1c, Rps1k, previously unidentified or multiple resistance gene to Phytophthora sojae (Rps) genes. Because they exhibited partial resistance equal to or greater than the standard check cultivar Conrad, three early MG soybean cultivars (MN0902, MN0302, and 91B53) were selected as standard checks to evaluate early MG PIs for partial resistance. Sixty-nine PIs were evaluated for partial resistance to P. sojae races 7 and 25 using the inoculum layer method. Of this group of PIs, 22 had the same level of partial resistance as Conrad to P. sojae race 7 while 19 had the same degree of partial resistance to race 25. Twelve PIs had same level of partial resistance as Conrad to both P. sojae races 7 and 25. The PIs and cultivars identified in this study will be of great value in developing early MG soybean cultivars suitable for planting in Canada and the northern United States.     

Genome-wide detection of genetic loci associated with soybean aphid resistance in soybean germplasm PI 603712

Soybean aphid (Aphis glycines Matsumura) has become one of the major pests of soybean [Glycine max (L.) Merr.] in North America since 2000. At least four biotypes of soybean aphid have been confirmed in the United States. Genetic characterization of new sources of soybean aphid resistance will facilitate the expansion of soybean gene pool for soybean aphid resistance and thus will help to develop soybean aphid resistant cultivars. To characterize the genetic basis of soybean aphid resistance in PI 603712, a newly identified resistant germplasm line, 142 F₂ plants derived from the cross ‘Roberts’ × PI 603712 and their parents were evaluated for soybean aphid resistance in the greenhouse, and were genotyped with BARCSoySNP6K Illumina Infinium II BeadChip. A genome-wide molecular linkage map was constructed with 1495 polymorphic SNP markers. QTL analysis revealed that PI 603712 possessed two major loci associated with soybean aphid resistance, located on chromosome 7 and 16, respectively. The locus on chromosome 7 was dominantly expressed and positioned about one Mega-base-pair distant from the previously identified resistance locus Rag1. The locus on chromosome 16 was positioned near the previously identified resistance locus Rag3 and expressed partially dominance or additive effect. Interestingly, two minor loci were also detected on chromosomes 13 and 17 but the alleles from PI 603712 decreased the resistance. In developing soybean aphid resistant cultivars through marker-assisted selection, an appropriate combination of resistance loci should be selected when PI 603712 is used as a donor parent of resistance.     

Testing inoculation methods and sources of resistance to the halo blight bacterium (Pseudomonas syringae pv. phaseolicola) in Phaseolus vulgaris

Summary A comparative test of six inoculation methods was conducted using 2 halo blight race 2 virulent strains, Nebr. HB 16 and HB 21 (Pseudomonas syringae pv. phaseolicola), on five dry bean cultivars/lines (Phaseolus vulgaris L.) of known resistance and susceptibility. The water-soaking of leaves method caused the most severe reaction among the leaf inoculation methods, followed by the carborundum, spraying and multiple needle methods, respectively. The seed soaking method was considered too severe to be useful, since entries identified as resistant by the other methods, were susceptible with the former method. Great Northern Nebraska # 1 sel. 27 and PI 150414 had the highest level of leaf resistance, but the former developed systemic chlorosis with the stem stabbing method, but not the latter line. No systemic chlorosis was seen in either line with the other methods of inoculation. This suggests that there may be a different genetic mechanism conferring resistance/susceptibility to the toxin in these two lines when the stabbing method is used. No interaction occurred between method by genotype and isolate by method but significant interactions occurred between genotype by isolate and method by isolate by genotype. The leaf and pod reaction of forty cultivars/lines to the new halo blight Nebr. Charlevoix strain was also determined. Different combinations of degrees of resistance and susceptibility of leaves and pods were observed. GN Tara, GN Harris, and PI 150414 had the highest combination of leaf and pod resistance.Published as paper No. 7094, Journal Series, Nebraska Agricultural Experiment Station. Research was conducted under Project No. 20-036.     

大豆花叶病毒(SMV)株系SC4和SC8的抗性遗传分析

选用我国黄淮和长江流域大豆产区发生频繁的SMV株系SC4和SC8,利用大豆抗病材料和感病材料配制抗感和抗抗杂交组合,研究抗病材料对SC4和SC8株系的遗传方式以及不同大豆材料对SMV抗性基因位点间的等位性关系。结果表明, 接种SC4株系后,由冀LD42、徐豆1号、跃进4号、科丰1号、PI96983、晋大74、汾豆56、大白麻和齐黄22为抗源配制的9个抗感组合的F₁均表现抗病,经卡方测验, F₂抗感分离比例3∶1,F_2:3家系分离比例为1(抗)∶2(分离)∶1(感),表明这些抗源均有1对基因控制对SC4株系的抗性,且抗病表现为显性;5个抗抗组合的F₁均表现抗病,F₂群体分离比例15(抗)∶1(感),表明大白麻与汾豆56、科丰1号和齐黄1号携带抗SC4的基因是不等位的,冀LD42与汾豆56,晋大74与中作229是不等位的。接种SC8株系后,用齐黄1号、中作229、NY58、科丰1号、PI96983、晋大74、汾豆56、大白麻和齐黄22为抗源配制的抗感组合杂交后代分离符合1对基因的分离比例且F₁均表现抗病,说明这些品种对SC8株系的抗性也均由1对显性基因控制。抗抗组合晋大74×汾豆56接种SC8株系后的F₂群体全部表现抗病,F_2:3家系没有抗感分离,表明抗病品种晋大74与汾豆56携带的抗病基因是等位的;齐黄1号×科丰1号、大白麻×汾豆56的F₂群体分离比例15(抗)∶1(感),表明抗病亲本齐黄1号与科丰1号、大白麻与汾豆56携带抗SC8的基因是不等位的,而且独立遗传。     

Genetic analysis of resistance to soybean cyst nematode in PI 438489B

Soybean (Glycine max L. Merr.) plant introduction PI 438489B is a unique source that has resistance to all known populations of soybean cyst nematode (Heterodera glycines Ichinohe, SCN). This PI line also has many desirable agronomic characteristics, which makes it an attractive source of SCN resistance for use in a soybean breeding program. However, characterization of SCN resistance genes in this PI line have not been fully researched. In this study, we investigated the inheritance of resistance to populations of SCN races 1, 2, 3, 5, and 14 in PI 438489B. PI 438489B was crossed to the susceptible cultivar ‘Hamilton’ to generate F₁ hybrids. The random F₂ plants and F₃ lines were evaluated in the greenhouse for reaction to these five populations of SCN races. Resistance to SCN races 1, 3, and 5 were mostly conditioned by three genes (Rhg Rhg rhg). Resistance to race 2 was controlled by four genes (Rhg rhg rgh rgh). Three recessive genes were most likely involved in giving resistance to race 14. We further concluded that resistance to different populations of SCN races may share some common genes or pleiotropic effects may be involved. This revised version was published online in July 2006 with corrections to the Cover Date.     

中品95-5117抗大豆花叶病毒基因源分析

中品95-5117和中品95-5383是以中品661为亲本选育的抗东北花叶病毒病3号株系(SMV3)的大豆新品系。中品95-5383抗病基因的SCAR标记已被定位于大豆F连锁群(Chr.13),与抗病基因Rsv1紧密连锁。利用大豆F连锁群的34个对SSR标记引物及与抗病基因紧密连锁的SCAR标记SCN11及Rsv1候选基因标记Rsv1-f/r,对中品95-5117系谱亲本进行检测,结合对SMV3的抗性鉴定结果进行分析,旨在明确抗SMV3基因在系谱中的传递规律,为利用分子标记辅助选择培育抗SMV3新品种提供依据。通过SSR标记分析发现,中品95-5117和中品95-5383与亲本中品661的相似性最高,而与另外一个亲本鲁豆4号关系较远。SCAR标记SCN11检测表明,只有1份材料Mangnolid(F-53)B为感病基因型。系谱的Rsv1-f/r标记分析表明,Williams82是中品95-5117中Rsv1基因的供体亲本。抗病性鉴定发现鲁豆4号高抗SMV3,但它并不携带Rsv1基因。据上述结果推测中品95-5117中不仅含有Rsv1,还具有来自鲁豆4号的抗病基因,证明该品系比其亲本中品661具有对SMV3更强的抗性。     

Comparison of homozygous and heterozygous self-compatible seedlings in an almond breeding programme

Homozygous self-compatible almond cultivars have not been reported. It is unclear if they are more inferior than heterozygotes or simply have not yet been detected. To investigate if homozygous individual are generally inferior, the self-compatibility genotype, homozygous or heterozygous, was determined by stylar ribonuclease assay in a population of 241 almond trees obtained by self-fertilisation of self-compatible selections. The resulting zymograms showed that 129 of the seedlings were homozygous and 112 heterozygous. For three years the differences observed between these two classes of self-compatible individuals were analysed with respect to 16 agronomic characteristics. In general, there were no important differences between the two classes. Both showed a low degree of productivity, probably as a result of their inbred origin. Some selected homozygous individuals were used in crosses, which were planned so as to ensure the self-compatibility of 100% of the descendants and to eliminate the laborious task of testing the seedlings for self-compatibility. This revised version was published online in August 2006 with corrections to the Cover Date.     

Heterosis of interspecific soybean hybrids for traits related to N2 fixation

Summary Three greenhouse experiments were conducted to compare the performance of soybean (Glycine max (L.) Merr.), wild soybean (G. soja Sieb. et Zucc.), and soybean x wild soybean hybrids for traits relating to N₂ fixation including nodulation, acetylene reduction, nodule leghemoglobin concentration, and nitrogen (N) accumulation and dry matter (DM) accumulation. In all three experiments G. max generally exceeded G. soja in nodulation, acetylene reduction, and N and DM accumulation while the soybean possessed higher nodule leghemoglobin concentration. In Experiment I, the mean of the hybrids did not differ significantly from the G. max parent in nodule mass, acetylene reduction activity, nodule leghemoglobin concentration, or DM accumulation. The hybrids did exceed the soybean parent in N accumulation, thus demonstrating high parent heterosis. In Experiments IIA and IIB with a more carefully chosen set of G. soja parents, high parent heterosis of individual crosses was common. Across the three experiments average high parent heterosis was 34, 28, and 28%, respectively, for nodule mass, N accumulation, and DM accumulation. If one accepts the assumption that hybrid vigor results from the accumulation of dominant alleles, then these alleles could theoretically be accumulated via selection in a homozygous genotype. If this is true than the results of the experiments reported here suggest that interspecific soybean x wild soybean crosses could serve as sources of homozygous lines which would exceed currently available soybean cultivars in nodule mass, and N and DM accumulation.This work was supported in part by the USDA Competitive Grants Program, Grant 82-CRCR-1-1039 and Cooperative Agreement 58-32U4-2-370 between the U.S. Department of Agriculture and the Agronomy Department, University of Maryland, Scientific Article No. A-4648, Contribution No. 7644 of the Maryland Agricultural Experiment Station.     

Inheritance of resistance to Xanthomonas campestris pv phaseoli in tetary bean (Phaseolus acutifolius)

Summary The F1, F2 and F3 from two crosses within Phaseolus acutifolius were exposed to Xanthomonas campestris pv phaseoli to analyse the inheritance of resistance. The resistant parent, PI 319.443, gave a hypersensitive reaction in leaves and pods with small necrotic lesions. Based on the resistance of F1, the segregation in F2 and the reaction of F3 plants and lines, it is concluded that resistance in leaves and pods is governed by one dominant gene. Comparisons are made with the resistance to X. campetris in P. vulgaris.     

14个毛豆品种对大豆疫病的田间抗性鉴定

通过田间小区对比试验,对14个毛豆品种抗大豆疫病的田间抗性进行鉴定,鉴定结果表明：表现明显抗病的品种有皖3126、思源、AGS292#、闽豆1221、通酥823、301#、茶豆和2808,这些品种可以在病区试种推广;表现感病的品种有绿光75、青酥2号和毛豆75。湿度是影响大豆疫病发生危害的最关键因素之一,实施轮作可减轻发病。